An opportunity of using solar energy to develop a multicomponent ceramic material synthesis technology using melts has been demonstrated. Optical and energy parameters of the 1 MW Large solar furnace for synthesizing aluminum titanate-based materials are presented along with their phase and grain size compositions depending on the melt cooling rate. A possibility of obtaining a two-phase material containing the tialite phase and spinel is shown. A positive effect of the spinel phase on the properties of ceramics made from the material synthesized by using solar energy has been established.
Similar content being viewed by others
References
L. Ya. Gavrilova, Synthesis methods and research of advanced materials, URGU, Yekaterinburg, 28 – 40 (2008).
A. B. Vorozhtsov, A. S. Zhukov, T. D. Malinovskaya, and V. I. Sachkov, Synthesis of finely dispersed metal oxide materials, NTL, Tomsk, 143 – 160 (2014).
F. Trombe, and M. Foex, “The production of cold by means of solar radiation,” Solar Energy, 1(1), 51 – 52 (1957).
A. A. Litvakovskii, Molten cast refractory materials, Gosstroyizdat, Moscow, 308 (1959).
S. N. Ganz, A. P. Melnik, and V. N. Parkhomenko, Plasma in chemical technology, Tekhnika, Kiev, 176 (1969).
K. Tyson, J. Kmiec, J. V. Acrivos, et al., “Bond resonance in superconducting rapid cooled alloys: (Bi1.7Pb0.3Sr2Can–1CunO2n+4+δ)2, n = 1 to 9 detected by novel local atomic enhanced XRD (poster),” National ACS Meeting, San Diego, CA, March (2012).
D. D. Gulamova, “Polymorphism of zirconium and hafnium dioxides,” Zh. Neorg. Khim., 36(5), 1127 – 1130 (1991).
D. D. Gulamova, “Phase ratios in the tertiary ZrO2–MgO–Gd2O3 system depending on the synthesis method,” Zh. Neorg. Khim., 37(9), 2099 – 2105 (1992).
T. T. Riskiev, and D. D. Gulamova, “Properties of oxide materials synthesized in the solar furnace,” DAN, No. 2, 14 – 19 (2014).
D. D. Gulamova, “The use of the Large solar furnace for heat treatment of high-temperature oxide melts,” Geliotekhnika, No. 6, 12 – 15 (1996).
Solar high-temperature furnaces: reports, ed. by A. Baum, IL, Moscow, 470 (1960).
R. Y. Akbarov and M. S. Paizullakhanov, “Specific features of energy characteristics of the 1,000 kW capacity Large solar furnace,” Geliotekhnika, No. 3, 17 – 23 (2017).
A. E. Sheindlin, Radiation properties of solid materials: reference book, Énergiya, Moscow, 474 (1974).
http://ido.tsu.ru/schools/chem/data/res/neorg/uchpos/text/simple7.html.
S. A. Azimov, M. M. Melnik, D. D. Gulamova, and M. Kh. Sarkisova, “Study of aluminum titanate obtained in the solar furnace,” Neorg. Mat., 20(3), 469 – 471 (1981).
D. Sh. Turdiev, “Study of the heat resistance of ceramic products for use in glassmaking,” Refr. and Ind. Cer., 54(2), 132 – 134 (2013).
S. A. Azimov, D. D. Gulamova, and M. Kh. Sarkisova, USSR Inventor’s Certificate No. 241036, Int. Cl4 C 04 B 35/10 (1987).
T. T. Riskiev, D. D. Gulamova, M. Kh. Sarkisova, et. Al, USSR Inventor’s Certificate No. 275678, Int. Cl4 C 04 B 35/10 (1987).
Author information
Authors and Affiliations
Corresponding author
Additional information
Translated from Novye Ogneupory, No. 4, pp. 111 – 115, April, 2018.
Rights and permissions
About this article
Cite this article
Gulamova, D.D., Bakhronov, K.N., Bobokulov, S.K. et al. Ceramics Based on Aluminum Titanate Synthesized by Using Solar Energy. Refract Ind Ceram 59, 194–198 (2018). https://doi.org/10.1007/s11148-018-0205-5
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11148-018-0205-5